Techniques for communications power management based on system states

ABSTRACT

Techniques for communications based power management based on system states are described. An apparatus may comprise a communications sub-system having a control policy module, a controller and a first transceiver capable of operating at different communications rates. The control policy module may be operative to receive computing power state information and communications state information, determine a communications rate parameter for the first transceiver based on the computing power state information and the communications state information, and instruct the controller to modify a communications rate for the first transceiver based on the communications rate parameter. Other embodiments are described and claimed.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a non-provisional of, and claims priority to U.S.patent application Ser. No. 12/208,824 titled “TECHNIQUES FORCOMMUNICATIONS POWER MANAGEMENT BASED ON SYSTEM STATES” filed on Sep.11, 2008 (Docket No. P26508), which is a non-provisional application of,and claims priority to U.S. Patent Provisional Application Ser. No.60/973,038 titled “TECHNIQUES FOR COMMUNICATIONS POWER MANAGEMENT BASEDON SYSTEM STATES” filed on Sep. 17, 2007 (Docket No. P26508Z), and isrelated to U.S. Patent Provisional Application Ser. No. 60/973,031titled “BUFFERING TECHNIQUES FOR POWER MANAGEMENT” filed on Sep. 17,2007 (Docket No. P26506Z), U.S. Patent Provisional Application Ser. No.60/973,035 titled “TECHNIQUES FOR COMMUNICATIONS BASED POWER MANAGEMENT”filed on Sep. 17, 2007 (Docket No. P26507Z), and U.S. Patent ProvisionalApplication Ser. No. 60/973,044 titled “TECHNIQUES FOR COLLABORATIVEPOWER MANAGEMENT FOR HETEROGENEOUS NETWORKS” filed on Sep. 17, 2007(Docket No. P26509Z), all three of which are hereby incorporated byreference in their entirety.

BACKGROUND

Power management for electronic devices such as computer systems play animportant part in conserving energy, managing heat dissipation, andimproving overall system performance. Modern computers systems areincreasingly designed to be used in settings where a reliable externalpower supply is not available making power management to conserve energyimportant. Power management techniques allow certain components of acomputer system to be powered down or put in a sleep mode that requiresless power than while in active operation, thereby reducing the totalamount of energy consumed by a device over some period of time. Energyconservation is especially important for mobile devices to conservebattery power. Even when reliable external power supplies are availablecareful power management within the computing system can reduce heatproduced by the system enabling improved performance of the system.Computing systems generally have better performance at lower ambienttemperatures because key components can run at higher speeds withoutdamaging their circuitry. Consequently, there are many advantages toenhancing power management for electronic devices.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates one embodiment of a communications system.

FIG. 2 illustrates one embodiment of an apparatus.

FIG. 3 illustrates one embodiment of a first logic diagram.

FIG. 4 illustrates one embodiment of a second logic diagram.

DETAILED DESCRIPTION

Various embodiments may comprise one or more elements. An element maycomprise any structure arranged to perform certain operations. Eachelement may be implemented as hardware, software, or any combinationthereof, as desired for a given set of design parameters or performanceconstraints. Although an embodiment may be described with a limitednumber of elements in a certain topology by way of example, theembodiment may include more or less elements in alternate topologies asdesired for a given implementation. It is worthy to note that anyreference to “one embodiment” or “an embodiment” means that a particularfeature, structure, or characteristic described in connection with theembodiment is included in at least one embodiment. The appearances ofthe phrase “in one embodiment” in various places in the specificationare not necessarily all referring to the same embodiment.

Various embodiments may be generally directed to techniques forcommunications power management based on system or platform powerstates. Some embodiments may be particularly directed to enhanced powermanagement techniques to manage power states for a communicationsportion of a node using computing power state information for acomputing portion of the node. In one embodiment, for example, thecomputing power state information may be communicated over acommunications bus and uniform interfaces between the various portionsof a node using various power management messages. Examples for a nodemay include various types of heterogeneous network endpoint andinfrastructure devices or resources, such as computers, servers,switches, routers, bridges, gateways, and so forth. The computing powerstate information may indicate, for example, whether a computing portionof a given node is operating in a power-managed state or afull-computation state, the duration for a power-managed state, a resumelatency to exit from a power-managed state, and other power relatedcharacteristics for the computing portion of the node. The computingpower state information may be used to perform power managementoperations for the communications portion of the node. For example, thecomputing power state information may be used by a control policy toselect a communications rate or link rate for the communications portionof the node, thereby directly or indirectly selecting a power state forthe communications portion of the node. In another example, thecomputing power state information may be used to directly switch thecommunications portion of the node to another power state. The powermanagement techniques may be implemented, for example, by power gatingand/or clock gating various hardware elements of a node, therebyconserving battery power.

In one embodiment, an apparatus such as a network device may include amanaged power system and a power management module to manage powerstates for the managed power system. The managed power system maycomprise, for example, any devices, components, modules, circuits, orother portions of the node drawing power from a power source, such as abattery. In one embodiment, for example, the managed power system maycomprise a computing sub-system. The computing sub-system may include acomputing state module operative to determine computing power stateinformation. The computing power state information may include, forexample, power states for the computing sub-system, as well as one ormore parameters representing certain characteristics of the powerstates, such as idle durations, resume latencies, and so forth. Thecomputing state module may send a power management message with thecomputing power state information to the power management module.

The power management module may be operative to communicate power stateinformation with the computing sub-system and the communicationssub-system utilizing various power management messages communicated overa communications bus and appropriate interfaces for the node. The powermanagement module may include a power management controller operative toreceive the power management message, retrieve the computing power stateinformation from the power management message, and determine a computingpower state parameter for the computing sub-system. The power managementcontroller may send the computing power state information, including thecomputing power state parameter, to a communications sub-system of themanaged power system.

The managed power system may further comprise a communicationssub-system. The communications sub-system may include a control policymodule and one or more transceivers capable of operating at differentcommunications rates. The control policy module may be operative toreceive computing power state information from the power managementmodule, and communications state information from a network state moduleof the communications sub-system, and determine a communications rateparameter for the one or more transceivers based on the computing powerstate information and the communications state information. The controlpolicy module may direct a controller to modify a communications ratefor the one or more transceivers based on the communications rateparameter. A lower communications rate typically lowers powerconsumption for the communications sub-system. In this manner, differentportions of a node such as a network device may exchange, negotiate andsynchronize power state information to improve or enhance power statemanagement for the communications sub-system of the network device inorder to facilitate energy conservation across the entire networkdevice.

FIG. 1 illustrates a block diagram of a communications system 100. Invarious embodiments, the communications system 100 may comprise multiplenodes 110-1-m. A node generally may comprise any physical or logicalentity for communicating information in the communications system 100and may be implemented as hardware, software, or any combinationthereof, as desired for a given set of design parameters or performanceconstraints. Although FIG. 1 may show a limited number of nodes in acertain topology by way of example, it can be appreciated that more orless nodes may be employed in different topologies for a givenimplementation.

In various embodiments, the communications system 100 may comprise, orform part of, a wired communications system, a wireless communicationssystem, or a combination of both. For example, the communications system100 may include one or more nodes 110-1-m arranged to communicateinformation over one or more types of wired communications links, suchas a wired communications link 140-1. Examples of the wiredcommunications link 140-1 may include without limitation a wire, cable,bus, printed circuit board (PCB), Ethernet connection, peer-to-peer(P2P) connection, backplane, switch fabric, semiconductor material,twisted-pair wire, co-axial cable, fiber optic connection, and so forth.The communications system 100 also may include one or more nodes 110-1-marranged to communicate information over one or more types of wirelesscommunications links, such as wireless shared media 140-2. Examples ofthe wireless shared media 140-2 may include without limitation a radiochannel, infrared channel, radio-frequency (RF) channel, WirelessFidelity (WiFi) channel, a portion of the RF spectrum, and/or one ormore licensed or license-free frequency bands. In the latter case, thewireless nodes may include one more wireless interfaces and/orcomponents for wireless communications, such as one or more radios,transmitters, receivers, transceivers, chipsets, amplifiers, filters,control logic, network interface cards (NICs), antennas, antenna arrays,and so forth. Examples of an antenna may include, without limitation, aninternal antenna, an omni-directional antenna, a monopole antenna, adipole antenna, an end fed antenna, a circularly polarized antenna, amicro-strip antenna, a diversity antenna, a dual antenna, an antennaarray, and so forth. In one embodiment, certain devices may includeantenna arrays of multiple antennas to implement various adaptiveantenna techniques and spatial diversity techniques.

As shown in the illustrated embodiment of FIG. 1, the communicationssystem 100 comprises multiple nodes 110-1-m. The nodes 110-1-m maycomprise or be implemented as any type of fixed or mobile electronicdevice or resource, including a network device, network endpointequipment, network infrastructure equipment, cellular radiotelephonenetwork equipment, a processing system, a computer system, a computersub-system, a computer, a workstation, a terminal, a server, a personalcomputer (PC), a laptop computer, an ultra-laptop computer, a portablecomputer, a handheld computer, a personal digital assistant (PDA), acellular telephone, a smart phone, a router, a switch, a bridge, agateway, a network appliance, a microprocessor, an integrated circuit, aprogrammable logic device (PLD), a digital signal processor (DSP), aprocessor, a circuit, a logic gate, a register, a microprocessor, anintegrated circuit, a semiconductor device, a chip, a transistor, and soforth. In some embodiments, some of the nodes 110-1-m may representheterogeneous network devices. In one embodiment, for example, the nodes110-1-m may comprise various mobile computer systems (e.g., laptopcomputers, handheld computers, smart phones, cellular telephones, and soforth) utilizing a mobile power source, such as one or more batteries.

In various embodiments, the nodes 110-1-m may be arranged to communicatevarious types of information in multiple communications frames asrepresented by the power management packet data units (PMPDU) 150-1-svia the network or communications links 140-1, 140-2. In variousembodiments, the nodes 110-1-m may be arranged to communicate controlinformation related to power management operations. Examples of controlinformation may include without limitation power information, stateinformation, power state information, power management commands, commandinformation, control information, routing information, processinginformation, system file information, system library information,software (e.g., operating system software, file system software,application software, game software), firmware, an applicationprogramming interface (API), a program, an applet, a subroutine, aninstruction set, an instruction, computing code, logic, words, values,symbols, and so forth. The nodes 110-1-m may also be arranged tocommunicate media information, to include without limitation varioustypes of image information, audio information, video information, AVinformation, and/or other data provided from various media sources.

Although some of the nodes 110-1-m may comprise different networkdevices, each of the nodes 110-1-m may include a common number ofelements as shown by the node 110-1. For example, the nodes 110-1-m mayeach include various power management elements to implement a powermanagement scheme operative to perform power management operations forthe nodes 110-1-m. In the illustrated embodiment shown in FIG. 1, forexample, a first node 110-1 may include a managed power system 120-1coupled to a power management module 130-1. The power management module130-1 of the first node may be operative to communicate power stateinformation with a second node (e.g., one of the nodes 110-2-m) over acommunications connection established via the communications links140-1, 140-2.

In general operation, the power management module 130-1 may managevarious power states for the managed power system 120-1 of the node110-1. The power state information may include past, present or futurepower states for one or more portions of a managed power system 120-1 ofthe node 110-1. In this manner, different portions of a managed powersystem 120-1 may exchange power state information to improve or enhancepower state management for the node 110-1. For example, the powermanagement module 130-1 may synchronize power management operationsbetween the sub-systems 210-1, 230-1 of the managed power system 120-1,such as placing communications components of the communicationssub-system 210-1 in a lower power state based on operations oranticipated operations for the computing components of the computingsub-system 230-1 for a given communications rate duration period. Thelower power state for the communications sub-system 210-1 may beachieved, for example, by switching to a power state for thecommunications sub-system 210-1 (e.g., Active to Idle), or a lower linkrate for the communications sub-system 210-1 (e.g., 10 Gb/s to 100Mb/s).

Although the node 110-1 is the only node shown in FIG. 1 to include themanaged power system 120-1 and the power management module 130-1, it maybe appreciated that each of the nodes 110-1-m may include an identicalor similar managed power system 120-1-n and power management module130-1-p. For example, the node 110-2 may include a managed power system120-2 coupled to a power management module 130-2, the node 110-3 mayinclude the elements 120-3, 130-3, and so forth. Furthermore, thedescriptions and examples of the structures and operations provided withreference to the managed power system 120-1 and the power managementmodule 130-1 may also apply to the corresponding elements in the othernodes 110-2-m. Exemplary embodiments for the managed power system120-1-n and the power management module 130-1-p may be described in moredetail with reference to FIG. 2.

The managed power system 120-1 and the power management module 130-1 maybe suitable for various use scenarios or applications. In someembodiments, for example, the managed power system 120-1 and the powermanagement module 130-1 may utilize enhanced power management techniquesimplemented in the form of one or more control policies for link ratemanagement of a communications device in accordance with the EnergyEfficient Ethernet (EEE) project. The goal of the EEE project is toreduce power consumption of network endpoint devices and infrastructureequipment. Many Ethernet communications links are idle most of the time,particularly for nodes implemented as desktop units (e.g., a personalcomputer or server). An EEE control policy attempts to match link rateswith link utilization for power efficiency. Typically lower link ratesconsume less power. For example, savings potential may be 2 to 4 Watts(W) per link for a 1 Gigabit Per Second (Gb/s) link versus a 100Megabits Per Second (Mb/s) link, and 10 to 20 W per link for a 10 Gb/slink versus a 1 Gb/s link. As a result, an existing network interfacecard (NIC) may lower the link rate to save power when entering lowerpower states for the NIC, such as a sleep power state, idle power state,off power state, and so forth. Switching between link rates, however,needs to be relatively fast to prevent dropping a connection withanother endpoint, typically on the order of 1-10 milliseconds (ms) orless.

To support fast switching between link rates, a communications portionof the nodes 110-1-m, such as a media access controller, may implement arapid physical layer (PHY) selection (RPS) technique. RPS is a techniqueor mechanism for fast switching of link rates, and is typicallysupported at both ends of a link. RPS techniques may be implemented in anumber of different ways, such as through a media access control (MAC)frame handshake operation, for example. RPS is typically limited,however, to rapid switching of link rates only.

RPS needs a control policy to determine when to switch link rates.Designing a control policy for RPS involves balancing multiple designparameters and performance constraints. One fundamental performancetrade-off, for example, is time in a given link rate versus packetdelay. If design priority is given to lowest possible packet delay, thenthe network endpoint should only use the highest link rate at all times.If design priority is given to lowest possible energy use, then thenetwork endpoint should only use the lowest link rate at all times. Agiven design solution attempts to have low and bounded packet delay withmaximum energy savings. One way to provide this design solution is bytriggering a switch in link rates based on threshold in output buffers.If a queue is above a certain threshold (or watermark) then the nodes110-1-m switches to a higher link rate. If a queue is below a certainthreshold (or watermark) then the network endpoint switches to a lowerlink rate. This type of control policy alone, however, may causefrequent oscillation between link rates, particularly when traffic isbursty, which is fairly typical for average users. Furthermore, thistype of control policy may force the nodes 110-1-m to enter a higherlink rate even when priority is given to energy conservation, such aswhen operating from a mobile power supply such as a battery. In somecases, for example, a user may desire a node 110-1-m to stay in a lowerpower state and maintain minimally tolerable network performance.

Various embodiments attempt to solve these and other problems. Someembodiments attempt to improve power management for a node 110-1-m byimplementing a control policy that supports RPS techniques whileallowing a computer system to aggressively and proactively power gateand/or clock gate portions of the computer system. For example, thecomputer system can manage power levels and link rates for variouscommunications elements based on the power levels and parameters of thecomputing elements, among other factors. To accomplish this, someembodiments utilize a parameterized communications device powermanagement technique that interfaces with the platform power managementarchitecture and conveys the idle duration, resume latency, and othercomputing power state information for the computing elements,components, modules, sub-systems or devices. By managing one or morepower-related aspects of the communications portions of a node 110-1-mbased on computing power state information, the node 110-1-m may realizeenhanced energy conservation and utilize limited power resources such asbatteries more efficiently.

FIG. 2 illustrates a more detailed block diagram for a managed powersystem 120 and a power management module 130. In the illustratedembodiment shown in FIG. 2, the managed power system 120 may include acomputing sub-system 230 and a communications sub-system 210. Thecomputing sub-system 230 may further include a computing state module232 and a power management interface 214-2. The communicationssub-system 210 may further include one or more transceivers 204-1-r, oneor more queues or buffers 26-1-t, a controller 208, a network statemodule 212, a power management interface 214-1, and a control policymodule 216. The power management module 130 may further include a powersource 212, a power management controller 234, and one or more powercontrol timers 236. The power management module 130 may also include apower management interface 214-3. The interfaces 214-1, 214-2 and 214-3may be coupled to a communications bus 220. Although FIG. 2 may show alimited number of elements in a certain arrangement by way of example,it can be appreciated that more or less elements may be employed indifferent arrangements for a given implementation.

In various embodiments, the managed power system 120 may include anyelectrical or electronic elements of the nodes 110-1-m consuming powerfrom the power source 212 and suitable for power management operations.Power management techniques allow certain components of an electronicdevice or system (e.g., a computer system) to be powered down or put inan idle mode or sleep mode that requires less power than while in activeoperation, thereby reducing the total amount of energy consumed by adevice over some period of time. The power management techniques may beimplemented by power gating and/or clock gating various hardwareelements of the managed power system 120, thereby conserving batterypower.

More particularly, the managed power system 120 may include variouselectrical or electronic elements of the nodes 110-1-m that can operatein various power states drawing multiple levels of power from the powersource 212 as controlled by the power management controller 234 of thepower management module 130. The various power states may be defined byany number of power management schemes. In some cases, for example, thepower states may be defined in accordance with the AdvancedConfiguration and Power Interface (ACPI) series of specifications,including their progeny, revisions and variants. In one embodiment, forexample, the power states may be defined by the ACPI Revision 3.0a, Dec.30, 2005 (the “ACPI Revision 3.0a Specification”). The ACPI series ofspecifications define multiple power states for electronic devices, suchas global system states (Gx states), device power states (Dx states),sleeping states (Sx states), processor power states (Cx states), deviceand processor performance states (Px states), and so forth. It may beappreciated that other power states of varying power levels may beimplemented as desired for a given set of design parameters andperformance constraints. The embodiments are not limited in thiscontext.

In some embodiments, the various electrical or electronic elements ofthe nodes 110-1-m suitable for power management operations may begenerally grouped or organized into the communications sub-system 210and the computing sub-system 230. It may be appreciated, however, thatthe sub-systems 210, 230 are provided by way of example for purposes ofclarity and not limitation, and the managed power system 120 may includeother electrical or electronic elements of the nodes 110-1-m suitablefor power management operations by the power management module 130. Forexample, the nodes 110-1-m may typically include a computer monitor ordisplay, such as a digital electronic display or an analog electronicdisplay. Examples of digital electronic displays may include electronicpaper, nixie tube displays, vacuum fluorescent displays, light-emittingdiode displays, electroluminescent displays, plasma display panels,liquid crystal displays, thin-film transistor displays, organiclight-emitting diode displays, surface-conduction electron-emitterdisplays, laser television displays, carbon nanotubes, nanocrystaldisplays, and so forth. An example for analog electronic displays mayinclude cathode ray tube displays. Computer monitors are often placed ina sleep mode when an operating system detects that the computer systemhas not received any input from a user for a defined period of time.Other system components may include digital cameras, touch screens,video recorders, audio recorders, storage devices, vibrating elements,oscillators, system clocks, controllers, and other platform or systemarchitecture equipment. These other system components can also be placedin a sleep or powered down state in order to conserve energy when thecomponents are not in use. The computer system monitors input devicesand wakes devices as needed. The embodiments are not limited in thiscontext.

In various embodiments, the managed power system 120 may include thecommunications sub-system 210. The communications sub-system 210 maycomprise various communications elements arranged to communicateinformation and perform communications operations between the nodes110-1-m. Examples of suitable communications elements may include anyelectrical or electronic element designed to communicate informationover the communications links 140-1, 140-2, including without limitationradios, transmitters, receivers, transceivers, chipsets, amplifiers,filters, control logic, interfaces, network interfaces, networkinterface cards (NICs), antennas, antenna arrays, digital signalprocessors, baseband processors, communications processors, media accesscontrollers, memory units, oscillators, clocks, and so forth.

In various embodiments, the managed power system 120 may include thecomputing sub-system 230. The computing sub-system 230 may comprisevarious computing elements arranged to process information and performcomputing operations for the nodes 110-1-m. Examples of suitablecomputing elements may include any electrical or electronic elementdesigned to perform logical operations or process information, includingwithout limitation processors, microprocessors, chipsets, controllers,microcontrollers, embedded controllers, clocks, oscillators, audiocards, video cards, multimedia cards, peripherals, memory units, memorycontrollers, video controllers, audio controllers, multimediacontrollers, bus controllers, hubs, and so forth.

In various embodiments, the power management module 130 may comprise apower source 212. The power source 212 may be arranged to provide powerto the elements of a node 110-1-m in general, and the managed powersystem 120 in particular. In one embodiment, for example, the powersource 212 may be operative to provide varying levels of power to thesub-systems 210, 230. In various embodiments, the power source 212 maybe implemented by a rechargeable battery, such as a removable andrechargeable lithium ion battery to provide direct current (DC) power,and/or an alternating current (AC) adapter to draw power from a standardAC main power supply.

In various embodiments, the power management module 130 may include apower management controller 234. The power management controller 234 maygenerally control power consumption for the managed power system 120. Inone embodiment, the power management controller 234 may be operative tocontrol varying levels of power provided to the sub-systems 210, 230 inaccordance with certain defined power states. For example, the powermanagement controller 234 may modify, switch, change or transition thepower levels provided by the power source 212 to the sub-systems 210,230 to a higher or lower power level, thereby effectively modifying apower state for the sub-systems 210, 230.

In various embodiments, the power management module 130 may include oneor more power control timers 236. The power control timer 236 may beused by the power management controller 234 to maintain a certain powerstate for a given power state duration period or communications rateduration period. The power state duration period may represent a definedtime interval one or more portions of the managed power system 120 is ina given power state. The communications rate duration period mayrepresent a defined time interval the communications sub-system 210communicates at a given communications rate. For example, the powermanagement controller 234 may switch the communications sub-system 210from a higher power state to a lower power state for a defined timeinterval set by the power state duration period, and when the timeinterval has expired, switch the communications sub-system 210 to thehigher power state. Similarly, the power management controller 234 mayswitch the communications sub-system 210 from a faster communicationsrate to a slower communications rate for a defined time interval set bythe communications rate duration period, and when the time interval hasexpired, switch the communications sub-system 210 to the fastercommunications rate.

In order to coordinate power management operations for a node 110-1-m,the sub-systems 210, 230 and the power management module 130 maycommunicate various power management messages 240-1-q via acommunications bus 220 and the respective power management interfaces214-1, 214-2, and 214-3. To manage power for all the devices in asystem, an operating system typically utilizes standard techniques forcommunicating control information over a particular Input/Output (I/O)interconnect. Examples of various I/O interconnects suitable forimplementation as the communications bus 220 and associated interfaces214 may include without limitation Peripheral Component Interconnect(PCI), PCI Express (PCIe), CardBus, Universal Serial Bus (USB), IEEE1394 FireWire, and so forth.

Referring again to FIG. 2, the communications sub-system 210 may includea network state module 212. The network state module 212 may be arrangedto monitor certain states or characteristics of the communicationssub-system 210, such as the network traffic activity of thecommunications connections 250-1-v, capabilities information,communications operational states for communications state machines, andother operations for the various communications elements of thecommunications sub-system 210. The network state module 212 may sendcommunications power management messages 240-1-q to the power managementmodule 130 with the measured characteristics. The power managementmodule 130 may generate power state information 260 for the managedpower system 120 based in part on the communications power managementmessages 240-1-q.

Similarly, the computing sub-system 230 may include a computing statemodule 232. The computing state module 232 may be arranged to monitorcertain states or characteristics of the computing sub-system 230, suchas the level of system activity, capabilities information, computingoperations states for computing state machines, and other operations forthe various computing elements of the computing sub-system 230. Thecomputing state module 232 may send computing power management messages240-1-q to the power management module 130 with the measuredcharacteristics. The power management module 130 may generate powerstate information 260 for the managed power system 120 based in part onthe computing power management messages 240-1-q.

In general operation, the power management module 130-1 may performpower management operations for portions of the managed power system120-1 of the node 110-1 based on power state information received fromother portions of the node 110-1. In some cases, for example, the powermanagement module 130-1 for the node 110-1 may be operative to receivecomputing power state information from the computing state module 232 ofthe computing sub-system 230-1 for the managed power system 120-1 overthe communications bus 220. The power management module 130-1 may managevarious communications power states and/or communications rates for thecommunications sub-system 210-1 of the managed power system 120-1 forthe node 110-1 based on the computing power state information for thecomputing sub-system 230-1. The power management module 130-1 and thesub-systems 210-1, 230-1 may communicate the computing power stateinformation over the communications bus 220 in accordance with variouscommunications bus protocols.

The computing power state information may represent informationexplicitly or implicitly related to power states for the computingsub-system 230. The computing power state information may also representvarious characteristics or attributes for the power states of thecomputing sub-system 230, such as such as computing power states, idledurations, resume latencies, and so forth. In one embodiment, forexample, the computing power state information may include withoutlimitation a computing power state parameter, a computing idle durationparameter, a computing resume latency parameter, and so forth.

As previously described, the power management module 130-1 may controlvarious power states for the managed power system 120-1 in accordancewith one or more power management standards, such as the ACPI standard.The ACPI standard may be suitable for defining the various power statesfor a portion of the managed power system 120-1, such as the computingsub-system 230-1 and/or the communications sub-system 210-1. Forexample, the power management module 130-1 may control power consumptionfor a processor and chipset of the communications sub-system 210-1 usingdifferent processor power consumption states (e.g., C0, C1, C2, and C3)as defined by the ACPI Revision 3.0a Specification. The power managementmodule 130-1 may send power control commands to the computing sub-system230-1 over the communications bus 220 and interfaces 214-2, 214-3.

In one embodiment, for example, the power management module 130 maycontrol power consumption for the computing sub-system 230 using anabbreviated set of power states from the ACPI Revision 3.0aSpecification referred to as system power states. The system powerstates define various power states specifically designed for thecomputing elements processing information for the nodes 110-1-m.Examples for the various system power states may be shown in Table 1 asfollows:

TABLE 1 System Power State Description S0 (On) This power stateindicates that the system is active and in full power mode. S0i1 (Idle1): This power state indicates that the system Duration, Latency isactive and in lower power mode than S0. S0i2 (Idle 2): This power stateindicates that the system Duration, Latency is active and in lower powermode than S0i1. S0i3 (Idle 3): This power state indicates that thesystem Duration, Latency is active and in lower power mode than S0i2. S2(Off) This power state indicates that the system is inactive and in offmode.As shown in Table 1, the system power states range from S0 to S2, wherethe S0 power state represents the highest power state with the maximumpower draw, the S0i1-S0i3 power states represents incrementally lowerpower states relative to the S0 power state with correspondingly lowerpower draws, and the S2 power state represents the lowest power statewith the minimum power draw (or none).

Some of the system power states have associated parameters. For example,the S0i1-S0i3 power states each have a pair of parameters referred to asa computing idle duration parameter and a computing resume latencyparameter. The computing idle duration parameter represents an amount oftime, or defined time interval, the computing sub-system 230 will remainin a given power state (e.g., S0i). The computing resume latencyparameter represents an amount of time, or defined time interval, thecomputing sub-system 230 needs to exit a given power state (e.g., S0i)and enter a higher power state (e.g., S0). The computing idle durationparameter and the computing resume latency parameter for the systempower states may be communicated by the power management messages240-1-q over the communications bus 220.

In various embodiments, the computing state module 232 may be arrangedto generate the computing idle duration parameter and the computingresume latency parameter based on the capabilities of the computingsub-system 230-1. For example, the computing sub-system 230-1 mayinclude various processors operating at different speeds, such as ahost, application or system processor. In another example, the computingsub-system 230-1 may include various memory units operating at differentread/write speeds. In still another example, the computing sub-system230-1 may include various I/O devices, such as a keyboard, mouse,display, memory controllers, video controllers, audio controllers,storage devices (e.g., hard drives), expansion cards, co-processors, andso forth. The computing state module 232 may evaluate these and othercomputing capabilities of the computing sub-system 230-1, and generatethe appropriate computing idle duration parameter and the computingresume latency parameter based on the evaluated capabilities of thecomputing sub-system 230-1.

Although in some embodiments the power states for the sub-systems 210-1,230-1 may be similarly defined and in synchronization, in someembodiments the power states may also be differently defined and notsynchronized for the sub-systems 210-1, 230-1. For example, the powermanagement module 130-1 may control power consumption for a radio ornetwork interface of the communications sub-system 210-1 using differentpower states than defined for the computing sub-system 230-1, asdescribed further below.

In various embodiments, the communications sub-system 210-1 may includeone or more transceivers 204-1-r capable of operating at differentcommunications rates. The transceivers 204-1-r may comprise anycommunications elements capable of transmitting and receivinginformation over the various wired media types (e.g., copper,single-mode fiber, multi-mode fiber, etc.) and wireless media types(e.g., RF spectrum) for communications link 140-1, 140-2. Examples ofthe transceivers 204-1-r may include various Ethernet-based PHY devices,such as a Fast Ethernet PHY device (e.g., 100Base-T, 100Base-TX,100Base-T4, 100Base-T2, 100Base-FX, 100Base-SX, 100BaseBX, and soforth), a Gigabit Ethernet (GbE) PHY device (e.g., 1000Base-T,1000Base-SX, 1000Base-LX, 1000Base-BX10, 1000Base-CX, 1000Base-ZX, andso forth), a 10 GbE PHY device (e.g., 10 GBase-SR, 10 GBase-LRM, 10GBase-LR, 10 GBase-ER, 10 GBase-ZR, 10 GBase-LX4, 10 GBase-CX4, 10GBase-Kx, 10 GBase-T, and so forth), a 100 GbE PHY device, and so forth.The transceivers 204-1-r may also comprise various radios or wirelessPHY devices, such as for mobile broadband communications systems.Examples of mobile broadband communications systems include withoutlimitation systems compliant with various Institute of Electrical andElectronics Engineers (IEEE) standards, such as the IEEE 802.11standards for Wireless Local Area Networks (WLANs) and variants, theIEEE 802.16 standards for Wireless Metropolitan Area Networks (WMANs)and variants, and the IEEE 802.20 or Mobile Broadband Wireless Access(MBWA) standards and variants, among others. The transceivers 204-1-rmay also be implemented as various other types of mobile broadbandcommunications systems and standards, such as a Universal MobileTelecommunications System (UMTS) system series of standards andvariants, a Code Division Multiple Access (CDMA) 2000 system series ofstandards and variants (e.g., CDMA2000 1xRTT, CDMA2000 EV-DO, CDMAEV-DV, and so forth), a High Performance Radio Metropolitan Area Network(HIPERMAN) system series of standards as created by the EuropeanTelecommunications Standards Institute (ETSI) Broadband Radio AccessNetworks (BRAN) and variants, a Wireless Broadband (WiBro) system seriesof standards and variants, a Global System for Mobile communications(GSM) with General Packet Radio Service (GPRS) system (GSM/GPRS) seriesof standards and variants, an Enhanced Data Rates for Global Evolution(EDGE) system series of standards and variants, a High Speed DownlinkPacket Access (HSDPA) system series of standards and variants, a HighSpeed Orthogonal Frequency-Division Multiplexing (OFDM) Packet Access(HSOPA) system series of standards and variants, a High-Speed UplinkPacket Access (HSUPA) system series of standards and variants, and soforth. The embodiments are not limited in this context.

The transceivers 204-1-r may individually or collectively operate atdifferent communications rates or link rates. In one embodiment, forexample, a single transceiver 204-1 may be capable of operating atvarious communications rates. In this case, when the control policymodule 216 determines the communications sub-system 210-1 should operateat a different communications rate, the control policy module 216 mayinstruct the controller 208 to switch the single transceiver 204-1 tothe desired communications rate. In another embodiment, for example, afirst transceiver 204-1 may be capable of operating at a firstcommunications rate, a second transceiver 204-2 may be capable ofoperating at a second communications rate, and so forth. When thecontrol policy module 216 determines the communications sub-system 210-1should operate at a different communications rate, the control policymodule 216 may instruct the controller 208 to switch operations from thefirst transceiver 204-1 to one of the transceivers 204-2-t arranged toprovide the desired communications rate.

In various embodiments, the communications sub-system 210-1 may includeone or more buffers 206-1-t. The buffers 206-1-t may be operative tostore network packets received by the transceivers 204-1-r, or ready fortransmission by the transceivers 204-1-r. For example, the buffers206-1-t may be used to buffer packets until the communications rate forthe transceiver has been completely switched or modified since switchingcommunications rates for the transceivers 204-1-r is typically notinstantaneous. The buffers 206-1-t may be implemented, for example, asstandard First-In-First-Out (FIFO) queues.

In various embodiments, the communications sub-system 210-1 may includea controller 208. The controller 208 may be arranged to controlswitching between communications rates by the transceivers 204-1-r. Inone embodiment, for example, the controller 208 may be arranged toimplement fast switching of communications rates utilizing RPStechniques in accordance with the EEE project. RPS is a technique ormechanism for fast switching of communications rates, and is typicallysupported at both ends of a link. For example, the communicationssub-system 210-1 of the first node 110-1 may implement RPS operations,and the communications sub-system 210-2 of the second node 110-2 mayalso implement corresponding RPS operations. The RPS operations may beimplemented in a number of different ways, such as through a MAC framehandshake operation, for example. The controller 208 may be implementedas any computing elements or logic device capable of executing logicaloperations, such as processors, microprocessors, chipsets, controllers,microcontrollers, embedded controllers, and so forth.

In various embodiments, the communications sub-system 210-1 may includea control policy module 216. The control policy module 216 may bearranged to implement one or more control policies to determine when thecontroller 208 should have the transceivers 204-1-r switchcommunications rates. The control policy module 216 may implementcontrol policies to enhance energy conservation for the nodes 110-1-m.For example, the control policy module 216 may implement controlpolicies compatible with the EEE project.

In one embodiment, the control policy module 216 may be operative toreceive computing power state information and communications stateinformation. The control policy module 216 may receive the computingpower state information indirectly from the power management module 130via the communications bus 220 and the interfaces 214-1, 214-3.Alternatively, the control policy module 216 may receive the computingpower state information directly from the computing sub-system 230 viathe communications bus 220 and the interfaces 214-1, 214-2. The controlpolicy module 216 may receive the communications state information fromthe network state module 212.

The control policy module 216 may receive the computing power stateinformation and/or the communications state information, and evaluate orcompare the computing power state information and the communicationsstate information against the control policies programmed for thecontrol policy module 216. The control policy module 216 may thendetermine a communications rate parameter for a transceiver 204-1-rbased on the analysis of the computing power state information and thecommunications state information. The communications rate parameter mayrepresent a given communications rate output providing a given level ofpower consumption programmed for the given computing power stateinformation and communications state information inputs. The controlpolicy module 216 may instruct the controller 208 to switch, change,transition or otherwise modify a communications rate for a transceiver204-1-r based on the communications rate parameter.

The control policy module 216 may implement various types of controlpolicies or rules to control when the controller 208 should switchcommunications rates. In one embodiment, for example, the control policymodule 216 may receive a computing power state parameter, a computingidle duration parameter and/or a computing resume latency parameter asthe computing power state information. The computing power stateparameter may represent a computing power state for the computingsub-system 230. The computing power state parameter may be generated,for example, by the power management controller 234 based on thecomputing power state information received from the computing sub-system230.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter. For example, the control policy module216 may have access to various control policies, rules or a lookup table(LUT) having certain communications rate parameters corresponding tocertain computing power state parameters, examples of which may be shownin Table 2 as follows:

TABLE 2 Computing Power State Parameter Communications Rate Parameter S0(On) CR0—Fastest rate (e.g., 100 Gb/s) S0i1 (Idle 1): CR1—Next fastestrate (e.g., 10 Gb/s) Duration, Latency S0i2 (Idle 2): CR2—Next fastestrate (e.g., 100 Mb/s) Duration, Latency S0i3 (Idle 3): CR3—Next fastestrate (e.g., 10 Mb/s) Duration, Latency S2 (Off) CR4—Lowest rate (e.g., 0Mb/s)As shown in Table 2, for example, the computing power state parameterrepresenting the highest power state S0 for the computing sub-system230-1 may have a corresponding communications rate parameterrepresenting the fastest communications rate CR0 for the communicationssub-system 210-1. When the control policy module 216 receives thecomputing power state information with a computing power state parameterrepresenting S0, for example, the control policy module 216 may accessthe information of Table 2 to determine the communications rateparameter of CR0, and pass the communications rate parameter to thecontroller 208. The controller 208 may then switch the transceivers204-1-r to the communications rate CR0 identified by the communicationsrate parameter.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter and other information, such as varioustypes of computing power state information, various types ofcommunications state information, and so forth. The control policymodule 216 may implement various control policies or rules to implementthe various other types of information used to select a communicationsrate for the communications sub-system 210-1 at any given moment,thereby improving power management of the nodes 110-1-m.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter and various types of the communicationsstate information, such as a network utilization parameter. For example,the network state module 212 may be operative to monitor variouscommunications connections 250-1-v for one or both of the communicationslinks 140-1, 140-2 for a defined time period. The network state module212 may calculate an average transmit period and an average receiveperiod for the communications connections 250-1-v, and determine anetwork link utilization parameter based on the average transmit periodand the average receive period. The control policy module 212 mayreceive the network link utilization parameter as the communicationsstate information, and determine the communications rate parameter forthe transceiver 204-1-r based on the computing power state informationand the network link utilization parameter. By way of example, assumethe computing power state parameter is set at S0i2, and thecorresponding communications rate parameter for S0i2 is CR2. Furtherassume the network link utilization parameter indicates a high level ofutilization of the communications connections 250-1-v, thereby implyinga higher traffic load for the communications links 140-1, 140-2. Thecontrol policy module 216 may evaluate the network link utilizationparameter, and select a communications rate parameter of CR1 rather thanCR2 to account for the higher network link utilization parameter.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter and various types of the communicationsstate information, such as a buffer utilization parameter. The controlpolicy module 216 may be arranged to switch link rates based onthresholds in input and/or output buffers 206-1-t. If a queue or buffer206-1-t is above a certain threshold (or watermark), for example, thenthe control policy module 216 may instruct the controller 208 to switchthe transceivers 204-1-r to a higher link rate. If a queue or buffer206-1-t is below a certain threshold (or watermark), for example, thenthe control policy module 216 may instruct the controller 208 to switchthe transceivers 204-1-r to a lower link rate. For example, the networkstate module 212 may be arranged to compare a number of packets in abuffer 206-1-t with a threshold value to form the buffer utilizationparameter. The threshold value may represent a high watermark value or alow watermark value for the buffer 206-1-t. The network state module 212may determine a buffer utilization parameter based on the comparisonresults. By way of example, assume the computing power state parameteris set at S0i2, and the corresponding communications rate parameter forS0i2 is CR2. Further assume the buffer utilization parameter indicatesthe number of packets stored by the buffers 206-1-t is below a lowwatermark value, thereby implying a lower traffic load for thecommunications links 140-1, 140-2. The control policy module 216 mayevaluate the buffer utilization parameter, and select a communicationsrate parameter of CR3 rather than CR2 to account for the lower bufferutilization parameter.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter and various other types of computingpower state information, such as a computing idle duration parameter anda computing resume latency parameter. As previously described, thecomputing idle duration parameter represents a time interval thecomputing sub-system 230 will be in an idle state, and the computingresume latency parameter represents a time interval the computingsub-system 230 needs to switch power states. By way of example, assumethe computing power state parameter is set at S0i2, and thecorresponding communications rate parameter for S0i2 is CR2. Furtherassume the computing idle duration parameter is 100 millisecond (ms),and the computing resume latency parameter is 1 ms, thereby implyingthat the computing sub-system 230-1 will switch power states relativelysoon with some time interval for the resume period. The control policymodule 216 may evaluate the computing idle duration parameter and thecomputing resume latency parameter, and select a communications rateparameter of CR1 rather than CR2 to account for an anticipated switch toa higher power state by the computing sub-system 230-1.

In one embodiment, the control policy module 216 may determine thecommunications rate parameter for the transceivers 204-1-r based on thecomputing power state parameter, the computing idle duration parameter,the computing resume latency parameter, and the communications stateinformation. The control policy module 216 may have multiple controlpolicies or rules for each parameter similar to the previous examples,and select a communications rate for the transceivers 204-1-raccordingly.

In addition to, or in lieu of, performing power management operations byusing the control policy module 216 to select a communications rate forthe transceivers 204-1-r that saves energy, the power managementcontroller 234 may perform power management directly by receivingcommunications state information from the communications sub-system210-1, communications power state information from the communicationssub-system 210-1, and/or the computing power state information from thecomputing sub-system 230-1, and determine a communications power stateparameter appropriate for the communications sub-system 210-1. Forexample, in some embodiments the power states for the communicationssub-system 210-1 and the computing sub-system 230-1 may be similarlydefined and in synchronization. In this case, the power managementcontroller 234 may match the communications power state with thecomputing power state. In some embodiments, however, the communicationspower state information may also be differently defined and notsynchronized for the sub-systems 210, 230. For example, the powermanagement module 130-1 may control power consumption for a radio ornetwork interface of the communications sub-system 210-1 using differentpower states than defined for the computing sub-system 230-1. In oneembodiment, for example, the power management module 130-1 may controlpower consumption for the communications sub-system 210-1 using a set ofpower states referred to as network link power management (NLPM) powerstates. The NLPM power states define various network link power statesspecifically designed for the communications elements of thecommunications sub-system 210-1 communicating information over the givencommunications links 140-1, 140-2. Examples for the various NLPM powerstates may be shown in Table 3 as follows:

TABLE 3 NLPM Power State Description NL0 (On) This power state indicatesthat the network link is active and in full power mode. NL1 (Idle): Thispower state indicates that the network Duration, Latency link is activeand in low power mode. NL2 (Sleep): This power state indicates that thenetwork Duration, Latency link is inactive and in sleep mode. NL3 (Off)This power state indicates that the network link is inactive and in offmode.

As shown in Table 3, the NLPM power states range from NL0 to NL3, wherethe NL0 power state represents the highest power state with the maximumpower draw, the NL1 and NL2 power states represent incrementally lowerpower states relative to the NL0 power state with correspondingly lowerpower draws, and the NL3 power state represents the lowest power statewith the minimum power draw (or none). In this case, the powermanagement controller 234 may switch the communications sub-system 210-1to a communications power state (e.g., NL0-NL3) based on the computingpower state parameter for the computing sub-system 230-1. In addition,the power management controller 234 may utilize various parametersassociated with the NLPM power states, such as a communications idleduration parameter and a communications resume latency parameter. Thecommunications idle duration parameter represents an amount of time, ordefined time interval, the network link or communications sub-system210-1 will remain in a given power state (e.g., NL1, NL2). Thecommunications idle duration parameter allows the sub-systems 210-1,230-1 to enter and exit the lower power states with a deterministicmanner. The communications resume latency parameter represents an amountof time, or defined time interval, the network link or communicationssub-system 210-1 needs to exit a given power state (e.g., NL1, NL2) andenter a higher power state (e.g., NL0). The communications resumelatency parameter allows the sub-systems 210-1, 230-1 to determine howsoon it can expect the communications sub-system 210-1 to wake up and beready for providing services such as out-going transmission. Thecommunications idle duration parameter and the communications resumelatency parameter for the NLPM power states may be generated by thenetwork state module 212, and communicated by the power managementmessages 240-1-q over the communications bus 220.

In various embodiments, the network state module 212 may be arranged togenerate the communications idle duration parameter and thecommunications resume latency parameter based on the capabilities of thecommunications sub-system 210-1. For example, the communicationssub-system 210-1 may implement various buffers to store informationreceived from the communications connections 250-1-v, such as networkpackets, and forward the information for servicing and processing by thecomputing sub-system 230-1. In another example, the communicationssub-system 210-1 may also implement various buffers to store informationreceived from the communications bus 220, such as network packets, andforward the information for communications by the communicationssub-system 210-1 to other nodes 110-2-m over the communicationsconnections 250-1-v via the communications links 140-1, 140-2. In yetanother example, the communications sub-system 210-1 may include variouswired or wireless transceiver operating at different communicationsspeeds, such as the IEEE 802.3-2005 standard 10 Gigabit Ethernet (10 GbEor 10 GigE), the IEEE 802.3ba proposed standard 100 Gigabit Ethernet(100 GbE or 100 GigE), and so forth. In still another example, thecommunications sub-system 210-1 may include various processors operatingat different speeds, such as baseband or communications processor. Instill another example, the network state module 212 may monitor the rateof information being received over the communications connections250-1-v via the communications links 140-1, 140-2. In this example, thenetwork state module 212 of the communications sub-system 210-1 maymonitor the communications links 140-1, 140-2 to measure packetinter-arrival times. Other examples of communications capabilities mayinclude other network traffic load measurements on the communicationslinks 140-1, 140-2 (e.g., synchronous traffic, asynchronous traffic,burst traffic, and so forth), a signal-to-noise ratio (SNR), a receivedsignal strength indicator (RSSI), throughput of the communications bus220, physical layer (PHY) speed, power state information 260 for othernodes 110-2-m received via one or more PMPDU 150-1-s, and so forth. Thenetwork state module 212 may evaluate these and other network orcommunications capabilities of the communications sub-system 210-1, andgenerate the appropriate communications idle duration parameter and thecommunications resume latency parameter based on the evaluatedcapabilities of the communications sub-system 210-1. The powermanagement controller 234 may use any of these parameters in variouscombinations to determine an appropriate communications power state forthe communications sub-system 210-1, and send a power management message240-1-q to the communications sub-system 210-1 with a communicationspower state parameter to place the communications sub-system 210-1 in acommunications power state (e.g., an NLPM power state NL0-NL3)corresponding to the communications power state parameter.

FIG. 3 illustrates a logic flow 300 in accordance with one or moreembodiments. The logic flow 300 may be performed by various systemsand/or devices and may be implemented as hardware, software, and/or anycombination thereof, as desired for a given set of design parameters orperformance constraints. For example, the logic flow 300 may beimplemented by a logic device (e.g., processor) and/or logic (e.g.,instructions, data, and/or code) to be executed by a logic device. Forpurposes of illustration, and not limitation, the logic flow 300 isdescribed with reference to FIGS. 1 and 2.

The logic flow 300 may illustrate various operations for the nodes110-1-m in general, and the managed power system 120 and the powermanagement module 130 in particular. As shown in FIG. 3, the logic flow300 may receive computing power state information by a control policymodule at block 302. The logic flow 300 may receive communications stateinformation by the control policy module at block 304. The logic flow300 may determine a communications rate parameter for a transceiverbased on the computing power state information and the communicationsstate information at block 306. The logic flow 300 may modify acommunications rate for the transceiver based on the communications rateparameter at block 308. The embodiments are not limited in this context.

In one embodiment, the logic flow 300 may receive computing power stateinformation by a control policy module at block 302. For example, thecontrol policy module 216 may receive computing power state informationindirectly from the power management controller 234 via thecommunications bus 220 and interfaces 214-1, 214-3, or directly from thecomputing sub-system 230 via the communications bus 220 and interfaces214-1, 214-2. The computing power state information may include withoutlimitation a computing power state parameter, a computing idle durationparameter, a computing resume latency parameter, and so forth.

In one embodiment, the logic flow 300 may receive communications stateinformation by the control policy module at block 304. For example, thecontrol policy module 216 may receive communications state informationfrom the network state module 212. The communications state informationmay include without limitation a network utilization parameter, a bufferutilization parameter, and so forth.

In one embodiment, the logic flow 300 may determine a communicationsrate parameter for a transceiver based on the computing power stateinformation and the communications state information at block 306. Forexample, the control policy module 216 may determine a communicationsrate parameter (e.g., CR0-CR4) for a transceiver 204-1-r based on thecomputing power state information and the communications stateinformation.

In one embodiment, the logic flow 300 may modify a communications ratefor the transceiver based on the communications rate parameter at block308. For example, the control policy module 216 may modify acommunications rate for the transceiver 204-1-r based on thecommunications rate parameter.

FIG. 4 illustrates a logic flow 400 in accordance with one or moreembodiments. The logic flow 400 may be performed by various systemsand/or devices and may be implemented as hardware, software, and/or anycombination thereof, as desired for a given set of design parameters orperformance constraints. For example, the logic flow 300 may beimplemented by a logic device (e.g., processor) and/or logic (e.g.,instructions, data, and/or code) to be executed by a logic device. Forpurposes of illustration, and not limitation, the logic flow 400 isdescribed with reference to FIGS. 1 and 2.

The logic flow 400 may illustrate various operations for the nodes110-1-m in general, and the managed power system 120 and the powermanagement module 130 in particular. The illustrated embodiment shown inFIG. 4 described a more detailed logic flow for implementing a controlpolicy for the control policy module 216 of the communicationssub-system 210-1. As shown in FIG. 4, the power management controller234 may receive at block 402 power management information from varioussources of a node 110-1-m, including an operating system (OS), variousdevice drivers, various devices and so forth. The power managementcontroller 234 may determine a computing power state parameter for thecomputing sub-system 230-1 using the power management information atblock 404. The power management controller 234 may send the computingpower state parameter to the control policy module 216, which isreceived as one input for the control policy module 216. The controlpolicy module 216 may also receive a second input from the network statemodule 212. For example, the network state module 212 may start anetwork link utilization timer at block 420, and calculate one or morenetwork link utilization parameters at block 422. The network statemodule 212 may determine whether the network utilization parameter isabove a certain threshold value at diamond 424. If not, the networkstate module 212 may continue to re-calculate the network linkutilization parameters at blocks 420, 422 until the network linkutilization parameters are above the threshold value at diamond 424.When this occurs, the network state module 212 may pass the network linkutilization parameters to the control policy module 216 as the secondinput. The control policy module 216 may take the first and secondinputs, and determine a communications rate parameter for thecommunications sub-system 210-1 using the inputs. The controller 208 mayreceive the communications rate parameter from the control policy module216, and initiate a modification in a communications rate for one ormore transceivers 204-1-r at block 408. At block 410, the controller 208may perform flow control operations to modify the transceivers 204-1-rof the communications sub-system 210-1 of the first node 110-1, as wellas one or more transceivers of a network endpoint communicating with thefirst node 110-1, such as the transceivers 204-1-r of the communicationssub-system 210-2 of the second node 110-2. As the controller 208performs the needed operations to switch the communications rates forthe two sets of transceivers of nodes 110-1, 110-2, the communicationssub-system 210-1 may continue to receive transmit and receive packetsfor the transceivers 204-1-r of the communications sub-system 210-1 atblock 412. The controller 208 may store the transmit and receive packetsin one or more of the buffers 206-1-t during switching operations atblock 414. The controller 208 may determine whether the switchingoperations are complete at diamond 416. If not, the controller 208 maycontinue buffering the packets at block 412, 414 until the switchingoperations are completed. Once the switching operations are completed atdiamond 416, the communications sub-system 210-1 may continue transmitand receive operations at block 418.

In some cases, various embodiments may be implemented as an article ofmanufacture. The article of manufacture may include a computer-readablemedium or a storage medium arranged to store logic and/or data forperforming various operations of one or more embodiments. Examples ofcomputer-readable media or storage media may include, withoutlimitation, those examples as previously described. In variousembodiments, for example, the article of manufacture may comprise amagnetic disk, optical disk, flash memory or firmware containingcomputer program instructions suitable for execution by a generalpurpose processor or application specific processor. The embodiments,however, are not limited in this context.

Various embodiments may be implemented using hardware elements, softwareelements, or a combination of both. Examples of hardware elements mayinclude any of the examples as previously provided for a logic device,and further including microprocessors, circuits, circuit elements (e.g.,transistors, resistors, capacitors, inductors, and so forth), integratedcircuits, logic gates, registers, semiconductor device, chips,microchips, chip sets, and so forth. Examples of software elements mayinclude software components, programs, applications, computer programs,application programs, system programs, machine programs, operatingsystem software, middleware, firmware, software modules, routines,subroutines, functions, methods, procedures, software interfaces,application program interfaces (API), instruction sets, computing code,computer code, code segments, computer code segments, words, values,symbols, or any combination thereof. Determining whether an embodimentis implemented using hardware elements and/or software elements may varyin accordance with any number of factors, such as desired computationalrate, power levels, heat tolerances, processing cycle budget, input datarates, output data rates, memory resources, data bus speeds and otherdesign or performance constraints, as desired for a givenimplementation.

Some embodiments may be described using the expression “coupled” and“connected” along with their derivatives. These terms are notnecessarily intended as synonyms for each other. For example, someembodiments may be described using the terms “connected” and/or“coupled” to indicate that two or more elements are in direct physicalor electrical contact with each other. The term “coupled,” however, mayalso mean that two or more elements are not in direct contact with eachother, but yet still co-operate or interact with each other.

It is emphasized that the Abstract of the Disclosure is provided tocomply with 37 C.F.R. Section 1.72(b), requiring an abstract that willallow the reader to quickly ascertain the nature of the technicaldisclosure. It is submitted with the understanding that it will not beused to interpret or limit the scope or meaning of the claims. Inaddition, in the foregoing Detailed Description, it can be seen thatvarious features are grouped together in a single embodiment for thepurpose of streamlining the disclosure. This method of disclosure is notto be interpreted as reflecting an intention that the claimedembodiments require more features than are expressly recited in eachclaim. Rather, as the following claims reflect, inventive subject matterlies in less than all features of a single disclosed embodiment. Thusthe following claims are hereby incorporated into the DetailedDescription, with each claim standing on its own as a separateembodiment. In the appended claims, the terms “including” and “in which”are used as the plain-English equivalents of the respective terms“comprising” and “wherein,” respectively. Moreover, the terms “first,”“second,” “third,” and so forth, are used merely as labels, and are notintended to impose numerical requirements on their objects.

Although the subject matter has been described in language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims. Examples of what could beclaimed include the following:

1. An apparatus, comprising: a communications sub-system having acontrol policy module, a controller and a first transceiver capable ofoperating at different communications rates, the control policy moduleoperative to receive computing power state information andcommunications state information, determine a communications rateparameter for the first transceiver based on the computing power stateinformation and the communications state information, and instruct thecontroller to modify a communications rate for the first transceiverbased on the communications rate parameter.
 2. The apparatus of claim 1,the control policy module operative to receive a computing power stateparameter with the computing power state information, and determine thecommunications rate parameter for the first transceiver based on thecomputing power state parameter.
 3. The apparatus of claim 1, thecontrol policy module operative to receive a computing power stateparameter with the computing power state information, and determine thecommunications rate parameter for the first transceiver based on thecomputing power state parameter and the communications stateinformation.
 4. The apparatus of claim 1, the control policy module toreceive a computing power state parameter, a computing idle durationparameter, and a computing resume latency parameter, and determine thecommunications rate parameter for the first transceiver based on thecomputing power state parameter, the computing idle duration parameter,the computing resume latency parameter, and the communications stateinformation.
 5. The apparatus of claim 1, comprising a network statemodule operative to monitor a communications link for a defined timeperiod, calculate an average transmit period and an average receiveperiod, and determine a network link utilization parameter based on theaverage transmit period and the average receive period.
 6. The apparatusof claim 1, the control policy module operative to receive a networklink utilization parameter as the communications state information, anddetermine the communications rate parameter for the first transceiverbased on the computing power state information and the network linkutilization parameter.
 7. The apparatus of claim 1, comprising a bufferto couple to the transceiver, the buffer operative to buffer packets forthe first transceiver, the network state module to compare a number ofpackets in the buffer with a threshold value, and determine a bufferutilization parameter based on the comparison.
 8. The apparatus of claim1, the control policy module operative to receive a buffer utilizationparameter as the communications state information, and determine thecommunications rate parameter for the first transceiver based on thecomputing power state information and the buffer utilization parameter.9. The apparatus of claim 1, comprising a buffer to couple to thetransceiver, the buffer operative to buffer packets until thecommunications rate for the transceiver has been modified.
 10. Theapparatus of claim 1, the controller to perform flow control operationsto modify a communications rate for a second transceiver based on thecommunications rate parameter.
 11. A system, comprising: a node having amanaged power system with a digital electronic display and acommunications sub-system, the communications sub-system having a firsttransceiver, a controller, and a control policy module, the firsttransceiver capable of operating at different communications rates, thecontrol policy module operative to receive computing power stateinformation and communications state information, determine acommunications rate parameter for the first transceiver based on thecomputing power state information and the communications stateinformation, and instruct the controller to modify a communications ratefor the first transceiver based on the communications rate parameter.12. The system of claim 11, the control policy module operative toreceive a computing power state parameter with the computing power stateinformation, and determine the communications rate parameter for thefirst transceiver based on the computing power state parameter and thecommunications state information.
 13. The system of claim 11, comprisinga power management module having a power management controller operativeto receive computing power state information from a computingsub-system, the computing power state information to include a computingidle duration parameter and a computing resume latency parameter, thepower management controller to determine a computing power stateparameter for the computing sub-system, and send a power managementmessage to the control policy module with the computing power stateinformation including the computing power state parameter, the computingidle duration parameter and the computing resume latency parameter. 14.The system of claim 11, comprising a computing sub-system having acomputing state module operative to generate the computing power stateinformation for the computing sub-system, and send a power managementmessage with the computing power state information to a power managementmodule.
 15. The system of claim 11, the communications sub-system havinga second transceiver, the control policy module to switch operationsfrom the first transceiver to a second transceiver to modifycommunications rates.
 16. A method, comprising: receiving computingpower state information by a control policy module; receivingcommunications state information by the control policy module;determining a communications rate parameter for a transceiver based onthe computing power state information and the communications stateinformation; and modifying a communications rate for the transceiverbased on the communications rate parameter.
 17. The method of claim 16,comprising: receiving a computing power state parameter, a computingidle duration parameter and a computing resume latency parameter as thecomputing power state information; and determining the communicationsrate parameter for the transceiver based on the computing power stateparameter, the computing idle duration parameter, the computing resumelatency parameter, and the communications state information.
 18. Themethod of claim 16, comprising: monitoring a communications link for adefined time period; calculating an average transmit period and anaverage receive period; and determining a network link utilizationparameter based on the average transmit period and the average receiveperiod.
 19. The method of claim 16, comprising: receiving a network linkutilization parameter as the communications state information; anddetermining the communications rate parameter for the transceiver basedon the computing power state information and the network linkutilization parameter.
 20. The method of claim 16, comprising: storingpackets for the first transceiver in a buffer; comparing a number ofpackets in the buffer with a threshold value; and determining a bufferutilization parameter based on the comparison.
 21. The method of claim16, comprising: receiving a buffer utilization parameter as thecommunications state information; and determining the communicationsrate parameter for the transceiver based on the computing power stateinformation and the buffer utilization parameter.
 22. An articlecomprising a computer-readable medium containing instructions that ifexecuted enable a system to: receive computing power state informationby a control policy module; receive communications state information bythe control policy module; determine a communications rate parameter fora transceiver based on the computing power state information and thecommunications state information; and modify a communications rate forthe transceiver based on the communications rate parameter.
 23. Thearticle of claim 22, further comprising instructions that if executedenable the system to: receive a computing power state parameter, acomputing idle duration parameter and a computing resume latencyparameter as the computing power state information; and determine thecommunications rate parameter for the transceiver based on the computingpower state parameter, the computing idle duration parameter, thecomputing resume latency parameter, and the communications stateinformation.
 24. The article of claim 22, further comprisinginstructions that if executed enable the system to: receive a networklink utilization parameter as the communications state information; anddetermine the communications rate parameter for the transceiver based onthe computing power state information and the network link utilizationparameter
 25. The article of claim 22, further comprising instructionsthat if executed enable the system to: receive a buffer utilizationparameter as the communications state information; and determine thecommunications rate parameter for the transceiver based on the computingpower state information and the buffer utilization parameter.